Electron microscopic observations of heterogeneous nuclear RNA of chicken reticulocytes

Core proteins I (Mr 50 000) and II (Mr 47 000) were isolated from beef heart ubiquinol-cytochrome c reductase, and radioimmunoassays were developed for both. Immunoreplica experiments show that antisera against each protein react with a single peptide in both isolated Complex III and in mitochondria. Thus, core proteins are not aggregated forms of smaller peptides as suggested for the yeast protein (Jeffrey, A., Power, S. and Palmer, G., Biochem. Biophys. Res. Commun. (1979) 86, 271-277). Core proteins were quantitated in Complex III and in mitochondria using radioimmunoassay. Approx. 2 mol core protein II per mol core protein I were found. A molar ratio of 1 : 2 : 2 : 1 is suggested for core protein I : core protein II : cytochrome b : cytochrome c1. Radioimmunoassay shows that the antibodies react as extensively with Complex III-bound core protein as with the isolated core proteins. In spite of this, the antibodies do not inhibit electron transport in submitochondrial particles or isolated Complex III, and they have no oligomycin- or uncoupler-like effects on submitochondrial particles oxidizing NADH. The combined results from radioimmunoassay and immunoreplica experiments strongly suggest, however, that core proteins are specifically associated with Complex III in the mitochondria, implying a specific role there.     

Studies on beef heart ubiquinol-cytochrome c reductase. Quantification and distribution of the core proteins as determined by radioimmunoassay

Core proteins I (M_r 50 000) and II (M_r 47 000) were isolated from beef heart ubiquinol-cytochrome c reductase, and radioimmunoassays were developed for both. Immunoreplica experiments show that antisera against each protein react with a single peptide in both isolated Complex III and in mitochondria. Thus, core proteins are not aggregated forms of smaller peptides as suggested for the yeast protein (Jeffrey, A., Power, S. and Palmer, G., Biochem. Biophys. Res. Commun. (1979) 86, 271–277). Core proteins were quantitated in Complex III and in mitochondria using radioimmunoassay. Approx. 2 mol core protein II per mol core protein I were found. A molar ratio of 1 : 2 : 2 : 1 is suggested for core protein I : core protein II : cytochrome b : cytochrome c₁. Radioimmunoassay shows that the antibodies react as extensively with Complex III-bound core protein as with the isolated core proteins. In spite of this, the antibodies do not inhibit electron transport in submitochondrial particles or isolated Complex III, and they have no oligomycin- or uncoupler-like effects on submitochondrial particles oxidizing NADH. The combined results from radioimmunoassay and immunoreplica experiments strongly suggest, however, that core proteins are specifically associated with Complex III in the mitochondria, implying a specific role there.     

Orientation of complex III in the yeast mitochondrial membrane: Labeling with [125I] diazobenzenesulfonate and functional studies with the decyl analogue of coenzyme Q as substrate

Mitochondria (or mitoplasts) and submitochondrial particles from yeast were treated with [¹²⁵I] diazobenzenesulfonate to label selectively proteins exposed on the outer or inner surface of the inner mitochondrial membrane. Polyacrylamide gel analysis of the immunoprecipitates formed with antibodies against Complex III or cytochromeb revealed that the two core proteins and cytochromeb were labeled in both mitochondria and submitochondrial particles, suggesting that these proteins span the membrane. Cytochromec ₁ and the iron sulfur protein were labeled in mitochondria but not in submitochondrial particles, suggesting that these proteins are exposed on the cytosolic side of the inner membrane. The steady-state reduction of cytochromesb andc ₁ was determined with succinate and the decyl analogue of coenzyme Q as substrates. Addition of the coenzyme Q analogue to mitochondria caused reduction of 15–30% of the total dithionite-reducibleb and 100% of the cytochromec ₁: Addition of the coenzyme Q analogue to submitochondrial particles led to the reduction of 70% of the total dithionite-reducible cytochromeb but insignificant amounts of cytochromec ₁. A model to explain the topography of Complex III in the inner membrane is proposed based on these results.Abbreviations used: DABS, diazobenzene sulfonate; DBH₂, reduced form of decyl analogue of coenzyme Q (2,3-dimethoxy-5-methyl-6-n-decyl-1,4-benzoquinone); PMSF, phenylmethylsulfonyl fluoride; SDS, sodium dodecyl sulfate.     

The orientation of transhydrogenase in the inner mitochondrial membrane of rat liver

The orientation of the transmembranous enzyme, pyridine dinucleotide transhydrogenase, in the inner mitochondrial membrane of rat liver has been determined by evaluating effects of proteases on the integrity of the enzyme in mitoplasts and submitochondrial particles. Following treatment of these membranes with the nonspecific protease, proteinase K, antigenic proteolytic products were detected by immunoblot analysis using polyclonal antibody prepared against purified bovine heart enzyme. Proteinase K treatment of mitoplasts converted the 110,000 transhydrogenase monomer into a single immunoreactive species having Mr 75,000. This proteolytic product is stable to further incubation with the protease. Treatment of submitochondrial particles with proteinase K resulted in the disappearance of the 110,000 monomer and the transient formation of an intermediate product with Mr 52,000. Information from these proteolysis studies was used to construct a model of the orientation of transhydrogenase in the inner mitochondrial membrane. This model indicates that transhydrogenase (Mr 110,000) contains a core of proteolytically inaccessible proteins within the membrane (Mr 23,000) bounded by extramembranous domains on the matrix (Mr 52,000) and cytoplasmic (Mr 35,000) face of the inner mitochondrial membrane.     

Arrangement of the subunits in solubilized and membrane-bound cytochrome c oxidase from bovine heart.

The arrangement of the six cytochrome c oxidase subunits in the inner membrane of bovine heart mitochondria was investigated. The experiments were carried out in three steps. In the first step, exposed subunits were coupled to the membrane-impermeant reagent p-diazonium benzene [32S]sulfonate. In the second step, the membranes were lysed with cholate anc cytochrome c oxidase was isolated by immunoprecipitation. In the third step, the six cytochrome c oxidase subunits were separated from each other by dodecyl sulfate-acrylamide gel electrophoresis and scanned for radioactivity. Exposed subunits on the outer side of the mitochondrial inner membrane were identified by labeling intact mitochondria. Exposed subunits on the matrix side of the inner membrane were identified by labeling sonically prepared submitochondrial particles in which the matrix side of the inner membrane is exposed to the suspending medium. Since sonic irradiation leads to a rearrangement of cytochrome c oxidase in a large fraction of the resulting submitochondrial particles, an immunochemical procedure was developed for isolating particles with a low content of displaced cytochrome c oxidase. With mitochondria, subunits II, V, and VI were labeled, whereas in purified submitochondrial particles most of the label was in subunit III. The arrangement of cytochrome c oxidase in the mitochondrial inner membrane is thus transmembraneous and asymmetric; subunits II, V, and VI are situated on the outer side, subunit III is situated on the matrix side, and subunits I and IV are buried in the interior of the membrane. In a study of purified cytochrome c oxidase labeled with p-diazonium benzene [32S]sulfonate, the results were similar to those obtained with the membrane-bound enzyme. Subunits I and IV were inaccessible to the reagent, whereas the other four subunits were accessible. In contrast, all six subunits became labeled if the enzyme was dissociated with dodecyl sulfate before being exposed to the labeling reagent.     

The orientation of d-β-hydroxybutyrate dehydrogenase in the mitochondrial inner membrane

d-β-Hydroxybutyrate dehydrogenase of beef heart mitochondria is a lipid-requiring enzyme, bound to the inner membrane. The orientation of this enzyme in the membrane has been studied by comparing the characteristics of the enzyme in mitochondria and ‘inside-out’ submitochondrial vesicles. We observe that the enzymic activity is (1) latent in intact mitochondria; (2) relatively stable to trypsin digestion in mitochondria but rapidly inactivated in submitochondrial vesicles by this treatment; and (3) released more rapidly from submitochondrial vesicles by phospholipase A₂ digestion than from mitochondria. Conclusive evidence that d-β-hydroxybutyrate dehydrogenase is localized on the matrix face of the mitochondrial inner membrane is provided by the correlation that the enzyme is released from submitochondrial vesicles before the membrane becomes leaky to cytochrome $\text{c}$. The arrangement of d-β-hydroxybutyrate dehydrogenase in the membrane is discussed within a generalized classification of the orientation of proteins in membranes. The evidence indicates that d-β-hydroxybutyrate dehydrogenase is an amphipathic molecule and as such is inlaid in the membrane, i.e. the enzyme is partially inserted into the hydrophobic milieu of the membrane, with the polar, functional end extending into the aqueous milieu.     

Studies on the immunological properties of complex V (mitochondrial ATP synthetase complex)

Antibody raised in rabbits against Complex V (miochondrial ATP synthetase complex) purified from beef heart mitochondria cross-reacted with Complex V and submitochondrial particles from beef heart, beef adrenals, and rat liver as shown by double-diffusion and rocket immunoelectrophoresis analysis. Of the various isolated and purified components of Complex V, only the oligomycin sensitivity-conferring protein showed strong reactivity with the anti-Complex V antibody, soluble F₁-ATPase reacted very faintly, while F₆ and ATPase inhibitor protein showed no precipitin lines. Crossed immunoelectrophoresis indicated that antigenic determinants recognized by the antibody were present on OSCP and possibly on the dicyclohexylcarbodiimide-binding protein. The components of Complex V could be precipitated from beef heart submitochondrial particles dissolved in Triton X-100 and pretreated with control IgG. When the composition of the immunoprecipitate was compared to that of purified Complex V, all the constituent polypeptides of the latter were present in the immunoprecipitate, except for one polypeptide in the low-molecular-weight region. Incubation of Complex V or submitochondrial particles with the anti-Complex V antibody in the absence of Triton X-100 caused inhibition of ATP-P_i exchange but not of ATPase activity. In the presence of Triton X-100, oligomycin sensitivity of Complex V was lost and the antibody was able to inhibit also the ATPase activity. The enzymic activity of soluble F₁-ATPase was unaffected by the antibody in the absence or presence of Triton X-100. These results suggest that the anti-Complex V antibody might be a useful tool for identifying and probing the role of Complex V components involved in energy transduction.     

The morphology and configurational states of isolated heavy beef heart mitochondria by the freeze fracture technique

Configurational changes of glutaraldehyde fixed heavy beef heart mitochondria are confirmed using the freeze fracture technique. Large amplitude swelling occurred after unfixed mitochondria were suspended in 30% glycerol. Fine structure of the outer and inner mitochondrial membranes is described using unfixed heavy beef heart mitochondria by the freeze fracture technique. The matrix side of the inner membrane appears to be covered with 90 Å particles while the opposite side (cytochromec side) is also particulate covered by a high density of lower profile particles with a smooth underlying mosaic layer beneath. The outer surface of the outer membrane is smooth with particles embedded within the membrane. Possible structure of the membrane is discussed.     

Subunit VII, the ubiquinone-binding protein, of the cytochrome b-c1 complex of yeast mitochondria is involved in electron transport at center o and faces the matrix side of the membrane

The functional role and topographical orientation in the inner membrane of subunit VII, the ubiquinone-binding protein, of the cytochrome b-c1 complex of yeast mitochondria has been investigated. The apparent molecular weight of this subunit on sodium dodecyl sulfate-urea gels was calculated to be 15,500, while its amino acid composition was similar to that of the Q-binding proteins present in the cytochrome b-c1 complexes isolated from both beef heart and yeast mitochondria. The specific antibody obtained against subunit VII inhibited 30-47% of the ubiquinol-cytochrome c reductase activity in the isolated cytochrome b-c1 complex and in submitochondrial particles but had no effect on cytochrome c reductase activity in mitoplasts, mitochondria from which the outer membrane has been removed. Furthermore, the antibody against subunit VII strongly inhibited (74%) the reduction of cytochrome b by succinate in the presence of antimycin, an inhibitor of center i, but had no effect on cytochrome b reduction in the presence of myxothiazol, an inhibitor of center o. These results suggest that subunit VII, the Q-binding protein, is involved in electron transport at center o of the cytochrome b-c1 complex of the respiratory chain and that subunit VII is localized facing the matrix side of the inner mitochondrial membrane.     

Proteomic analysis of mitochondria from the heart of <Emphasis Type="Italic">Bos taurus</Emphasis>. III. Identification of proteins of the inner mitochondrial membrane

Proteins of the inner mitochondrial membrane packed into submitochondrial particles (SMP) have been investigated. SMPs were treated with trypsin, and the peptides were separated from the so-called “shaved vesicles”. The “shaved vesicles” were disrupted, and the proteins and peptides obtained were subjected to cleavage by cyanogen bromide and trypsin. The two groups of tryptic peptides obtained were analyzed separately using proteomic methods, namely, chromatographic fractionation of peptides, mass spectrometric identification and a search in amino acid sequence databases. The possibility of non-specific fragmentation was also taken into account when identification of proteins of the inner mitochondrial membrane was performed. Reliable identification of 298 proteins allowed for a more precise estimation of their localization in the cell and analysis of their function.     

Proteolytic fragmentation of myosin: location of SH-1 and SH-2 thiols.

The heavy chain fragmentation pattern of native myosin when digested by proteolytic enzymes is influenced by such conditions as the nature of the proteolytic agent, ionic strength and presence or absence of divalent cations. HMM and S-1 produced by digestion of 14CNEM-labelled myosin under various conditions were analyzed by sodium dodecyl-sulfate polyacrylamide gel electrophoresis. Purified samples of these species were digested under controlled conditions by chymotrypsin and trypsin and a comparison of the observed heavy chain fragmentation patterns led to a sequential arrangement of the proteolytic fragments. The main features of this arrangement are the following: a 21K molecular weight tryptic peptide is found at the N-terminal side of myosin heavy chain. Adjacent to it is a 48K peptide, then a 19.5K peptide containing the two SH-1 and SH-2 thiols. These three peptides constitute the heavy chain of S-1. Adjacent to this S-1 heavy chain is a tryptic (and also chymotryptic) 40K peptide. The rest of the HMM heavy chain on the C-terminus is a sequence susceptible to both chymotrypsin and trypsin attack yielding an undefined number of small peptides.     

Immunological studies on beef-heart ubiquinol--cytochrome c reductase (complex III)

Antibodies against isolated beef-heart ubiquinol--cytochrome c reductase (complex III) have been characterized. Antibodies to complex III react strongly with isolated beef heart complex III and intact beef heart mitochondria, as shown by immunodiffusion and rocket electrophoresis experiments. The complex III content of intact mitochondria can be quantitated with rocket electrophoresis using isolated complex III as a standard. Antibodies to complex III also react with beef liver mitochondria and with both heart and liver mitochondria from rats. The latter are very weak antigens compared to beef heart material. Antibodies to complex III do not react with respiratory chain complexes I and IV, or F1-ATPase from beef heart mitochondria, but gives a slight, but variable, reaction with complex II and the membrane fraction isolated from complex V (oligomycin-sensitive ATPase). Antigenic sites are located on at least five of the seven peptides of complex III. These peptides are presumably lacking in respiratory chain complexes which do not react with antibodies to complex III, and are assumed to be uniquely located in complex III. Antiserum against complex III inhibitis duroquinol--cytochrome c reductase activity in isolated complex III and in complex III incorporated into phospholipid vesicles. Oxidation of NADH and succinate is not affected in submitochondrial particles treated with 6-times more antibody than required for complete inhibition of enzyme activity in free complex III or in complex III-phospholipid vesicles.     

Topology of subunits of the mammalian cytochrome c oxidase: relationship to the assembly of the enzyme complex.

The arrangement of three subunits of beef heart cytochrome c oxidase, subunits Va, VIa, and VIII, has been explored by chemical labeling and protease digestion studies. Subunit Va is an extrinsic protein located on the C side of the mitochondrial inner membrane. This subunit was found to label with N-(4-azido-2-nitrophenyl)-2-aminoethane[35S]sulfonate and sodium methyl 4-[3H]formylphenyl phosphate in reconstituted vesicles in which 90% of cytochrome c oxidase complexes were oriented with the C domain outermost. Subunit VIa was cleaved by trypsin both in these reconstituted vesicles and in submitochondrial particles, indicating a transmembrane orientation. The epitope for a monoclonal antibody (mAb) to subunit VIa was lost or destroyed when cleavage occurred in reconstituted vesicles. This epitope was localized to the C-terminal part of the subunit by antibody binding to a fusion protein consisting of glutathione S-transferase (G-ST) and the C-terminal amino acids 55-85 of subunit VIa. No antibody binding was obtained with a fusion protein containing G-ST and the N-terminal amino acids 1-55. The mAb reaction orients subunit VIa with its C-terminus in the C domain. Subunit VIII was cleaved by trypsin in submitochondrial particles but not in reconstituted vesicles. N-Terminal sequencing of the subunit VIII cleavage product from submitochondrial particles gave the same sequence as the untreated subunit, i.e., ITA, indicating that it is the C-terminus which is cleaved from the M side. Subunits Va and VIII each contain N-terminal extensions or leader sequences in the precursor polypeptides; subunit VIa is made without an N-terminal extension.     

Vesicular stomatitis virus glycoprotein is anchored to intracellular membranes near its carboxyl end and is proteolytically cleaved at its amino terminus.

The intracellular vesicular stomatitis virus glycoprotein (G) is inserted into membranes such that a small portion of one end of the molecule is exposed on the cytoplasmic surface of the endoplasmic reticulum and is susceptible to proteolytic digestion (T.G. Morrison, C.O. McQuain, and D. Simpson, J. Virol. 28:368-374). We have determined that this region of the G protein contains two methionyl tryptic peptides. The methionyl tryptic peptides of the G protein have been ordered by the use of the antibiotic pactamycin, and the two methionyl tryptic peptides removed by proteolytic digestion of intracellular G protein have been shown to be derived from the carboxyl terminal end of the protein. In addition, we have found that the unglycosylated G protein synthesized in a reticulocyte cell-free reaction migrates on polyacrylamide gels slightly slower than the unglycosylated G protein synthesized in tunicamycin-treated infected cells. We have also compared these G proteins derived from different sources by partial proteolysis (D.W. Cleveland, S.G. Fischer, M.W. Kirschner, and V.K. Laemmli, J. Biol. Chem. 252:1102-1106) and by chymotryptic peptide analysis. We have found minor differences between the two proteins consistent with the removal of 10 to 15 amino acids from the amino terminus of the intracellular G protein.     

Modification of the cation selectivity filter and the calcium receptor of the Ca-stimulated K channel in resealed ghosts of human red blood cells by low levels of incorporated trypsin

The transport properties of the Ca-activated, K channel in the resealed human blood cell ghost can be modified by the action of incorporated trypsin. Membranes were maximally depleted of diffusible cytoplasmic components by hemolysis on a gel filtration column at 0 degree C. Subsequently, isotonicity was restored and 0.01-1 microgram/ml trypsin incorporated. Partial digestion of the membrane proteins occurred during resealing. As the degree of tryptic digestion increased, the channel became initially permeable to K and later to both and Na; and then the channel became refractory to the action of applied Ca. The observations suggest that tryptic digestion of proteins at the inner membrane surface leads to modifications of the selectivity filter and the Ca-receptor site of the channel. The modifications probably stem from alterations at the inner surface of a transmembrane protein which acts as a channel. Under conditions where selectivity is lost, the channel is still inhibited by externally applied TbCl3 .     

Labeling of succinate-cytochrome c reductase with 125I. Accessibility of the peptides to the aqueous phases on the cytosolic and matrix sides of the mitochondrial membrane

Lactoperoxidase-catalyzed radioiodination was used to study the arrangement of the component peptides of succinate-cytochrome c reductase with respect to the aqueous phases on each side of the mitochondrial inner membrane. Mitochondria depleted of their outer membrane and inside-out vesicles purified from submitochondrial particles by the lectin-affinity procedure (D'Souza, M. P., and Lindsay, J. G. (1981) Biochim. Biophys. Acta 640, 463-472) were iodinated using immobilized preparations of lactoperoxidase. The labeled membranes were solubilized in detergent and the succinate-cytochrome c reductase was purified by immunoprecipitation with specific IgG. Analysis of the radioiodine distribution after sodium dodecyl sulfate-polyacrylamide gel electrophoresis and comparison with peptide stain patterns show that bands 2 (64 kilodaltons), 6 (30 kilodaltons), 9 (15 kilodaltons), and 11 (less than 10 kilodaltons) are labeled from the cytoplasmic surface of the membrane. Bands 1 (72 kilodaltons), 4 (48 kilodaltons), and 8 (20 kilodaltons) appear to be labeled on the matrix side of the membrane, while bands 3 (52 kilodaltons), 5 (35 kilodaltons), 7 (25 kilodaltons), and 10 (11 kilodaltons) are labeled from both sides of the membrane. Tentative identification of the labeled bands suggests that band 1 is the large subunit of succinate dehydrogenase. Bands 3 and 4 represent proteins which have been referred to as core proteins I and II. Bands 5 and 6 are the proteins associated with cytochromes b and c1, respectively; band 7 is the Rieske iron-sulfur protein.     

Novel isolation of ubiquinone-binding proteins located in different sites of beef heart mitochondrial respiratory chain

Ubiquinone-binding proteins were isolated from beef heart submitochondrial particles by a simple fractionation procedure using ethanol and ammonium acetate after solubilization of the particles with deoxycholate. The ubiquinone-binding proteins were further purified by passing them through a column of phenyl-Sepharose CL-4B to eliminate the free form of ubiquinone and hydrophobic proteins such as cytochromes. At least 25% of the total ubiquinone present in the submitochondrial particles was associated with the purified proteins. Applying the same method, ubiquinone-binding proteins could be isolated from complexes I and III.     

Transmembrane topography of the mitochondrial phosphate carrier explored by peptide-specific antibodies and enzymatic digestion

Two peptides corresponding to the amino acid sequences 1-10 (N-terminal peptide) and 303-313 (C-terminal peptide) of the bovine heart mitochondrial phosphate carrier have been synthesized. After being coupled to ovalbumin, they were injected into rabbits to raise polyclonal antibodies. The specificity of the generated antibodies was tested by enzyme-linked immunosorbent assay (ELISA) and/or Western blot. Anti-N-terminal antibodies and anti-C-terminal antibodies exclusively reacted with the corresponding terminal peptide, they also reacted with the isolated phosphate carrier as well as with the phosphate carrier protein in mitochondrial lysates. Both anti-N-terminal and anti-C-terminal antibodies bound to freeze-thawed mitochondria, indicating that both termini of the membrane-bound phosphate carrier are exposed to the cytoplasmic side of the inner mitochondrial membrane. These immunological data were complemented with results concerning enzymatic cleavage of the membrane-bound phosphate carrier by carboxypeptidase A and by an arginine-specific endoprotease. Carboxypeptidase A markedly decreased the binding of anti-C-terminal antibodies to phosphate carrier in freeze-thawed mitochondria. Arg-endoprotease cleaved the phosphate carrier in inside-out submitochondrial particles, but not in right-side-out particles, yielding two fragments of similar apparent molecular weight (Mr approximately equal to 14.5K), which were immunodetected only by the anti-N-terminal antiserum, and a fragment of Mr approximately equal to 17K which was detected only by the anti-C-terminal antiserum. It appears, therefore, that Arg-endoprotease cleavage sites of the phosphate carrier are present only at the matrix side of the inner mitochondrial membrane, at Arg-140 and/or Arg-152.(ABSTRACT TRUNCATED AT 250 WORDS)     

Von Willebrand factor A domain-containing protein 8 (VWA8) localizes to the matrix side of the inner mitochondrial membrane

VWA8 is a poorly characterized mitochondrial AAA + ATPase protein. The specific submitochondrial localization of VWA8 remains unclear. The purpose of this study was to determine the specific submitochondrial compartment within which VWA8 resides in order to provide more insight into the function of this protein. Bioinformatics analysis showed that VWA8 has a 34 amino acid N-terminal Matrix-Targeting Signal (MTS) that is similar to those in proteins known to localize to the mitochondrial matrix. Experiments in C2C12 mouse myoblasts using confocal microscopy showed that deletion of the VWA8 MTS (vMTS) resulted in cytosolic, rather than mitochondrial, localization of VWA8. Biochemical analysis using differential sub-fractionation of mitochondria isolated from rat liver showed that VWA8 localizes to the matrix side of inner mitochondrial membrane, similar to the inner mitochondrial membrane protein Electron Transfer Flavoprotein-ubiquinone Oxidoreductase (ETFDH). The results of these experiments show that the vMTS is essential for localization to the mitochondrial matrix and that once there, VWA8 localizes to the matrix side of inner mitochondrial membrane.     

Evaluation of the application of sodium deoxycholate to proteomic analysis of rat hippocampal plasma membrane

Detergents have been widely used for the solubilization of membrane proteins and the improvement of their digestion. In this paper, we have evaluated the application of sodium deoxycholate (SDC) to the solubilization and digestion of rat hippocampal plasma membrane (PM) proteins. For in-solution digestion, rat hippocampal PM fraction from sucrose-density gradient centrifugation was solubilized by boiling in 1.0% SDC, and directly digested without dilution. During the in-gel digestion of the hippocampal PM proteins separated by SDS-PAGE, 0.1% SDC was added. Before analysis of peptide mixture by liquid chromatography and electrospray mass spectrometry, SDC in the tryptic digests was removed by centrifugation following acidification. Use of 1.0% SDC in solubilization and in-solution digestion of rat PM proteins had led to 77 PM or membrane-associated proteins identified, a more than 2-fold increase over that by use of SDS. The addition of 0.1% SDC to the in-gel digestion of SDS-PAGE-resolved membrane proteins remarkably enhanced the coverage of tryptic peptides and the number of hydrophobic membrane proteins identified. Being a cheaper and more tractable acid-insoluble detergent, SDC could be used at higher concentration in the solubilization and tryptic digestion of proteins including PM proteins with the purpose of enhancing the protein solubility and at the same time making no interference with trypsin activity and subsequent analyses.